Downlight apparatus

ABSTRACT

A downlight apparatus includes a main housing, a light module, a diffusion cover and a light guide. The main housing has a surrounding wall and a base part. The light module is attached to the base part for emitting a first light and a second light. The diffusion cover is fixed to a bottom end of the surrounding wall, for converting the second light to a peripheral light on an exterior surface of the diffusion cover. The light guide has a light entrance side facing to the base part for directing the first light through the light guide to escape at a light escape side of the light guide. The light escape side of the light guide is surrounded by diffusion cover.

RELATED APPLICATION

The present application is a continued application of U.S. Fil

FIELD OF INVENTION

The present invention is related to a downlight apparatus and moreparticularly related to a downlight apparatus with multiple lightmodules.

BACKGROUND

There are various lighting devices designed for satisfying differentneeds. For example, there are light bulbs to be installed on sockets.Such light bulbs are usually easy to be installed by users. Fordownlight devices used in normal home, it would be important to considerconvenience for installation, safety and replacement.

Among light devices, downlight devices are popular. Various downlightdevices may be in lots of places around the world. Usually, there is acavity or an installation box in a ceiling. A downlight device isinstalled in the cavity or the installation box. Wires are connected toan external power source, like a 110V or 220V alternating current.

Sometimes, a control signal is also provided to the downlight device tocontrol a luminance level of the downlight device.

SUMMARY OF INVENTION

According to an embodiment of the present invention, a downlightapparatus includes a main housing, a light module, a diffusion cover,and a light guide.

The downlight apparatus may be attached to a standard U.S. or Europeanstandard downlight station. The main housing may be made of plastic as apiece, e.g. made via a molding procedure to produce a one-piececomponent. Alternatively, the main housing may contain multiple parts tobe assembled together or adding further components like driver circuitor heat sink.

The main housing has a surrounding wall and a base part. A top end ofthe surrounding wall fixed to the base part forming a cup containingspace. For example, a surrounding wall is extended from the base partwith a surrounding curved surface. The surrounding curved surface andthe base part together form a cup containing space for enclosing somecomponents mentioned below.

The light module may have one LED module or multiple LED modules. Wherethere are multiple LED modules, the multiple LED modules at differentpositions on a substrate or on different substrates. Some specificexamples are explained as follows.

The light module is at least partly attached to the base part, meaningthat at least some component of the LED module is directly or indirectlyattached to the base part of the main housing. Specifically, as anexample, when the main housing is made of plastic material, a metal heatsink may be disposed between the base part of the main housing and a LEDplate of the light module.

In addition, the light module emits a first light and a second light. Asmentioned above, the light module may have multiple LED modules foremitting the first light and the second light.

The diffusion cover is fixed to a bottom end of the surrounding wall forconverting the second light to a peripheral light on an exterior surfaceof the diffusion cover. Furthermore, the light guide has a lightentrance side facing to the base part for directing the first lightthrough the light guide to escape at a light escape side of the lightguide. In other words, there are two light output from the diffusioncover and the light guide respectively.

The light escape side of the light guide is surrounded by diffusioncover. The term “surround” does not need to limit the light escape sidebeing at the same plane as the diffusion cover. Instead, the term“surround” refers that in a two-dimension protection aspect, the lightescape side is surrounded by the diffusion cover. In other words, thelight escape side may be higher than the diffusion cover while stillbeing surrounded by the diffusion cover when being viewed from atwo-dimension bottom view. The term “surround” is explained similarlyfor other components in this disclosure.

In some embodiments, the downlight apparatus further includes a driver.The driver controls the light module to emit the first light and thesecond light separately. In other words, the driver may be connected toa wire or wireless switch for users to manually control or for programcodes to automatically control so as to turn on or turn off the firstlight and the second light separately. Specifically, the first light maybe turned on while the second light is turned off, the first light maybe turned off while the second light is turned on, or the first lightand the second light are turned on at the same time. The luminancestrength of the first light and the second light, when needed, may betuned separately or with a predetermined relation, depending ondifferent design needs.

In some embodiments, the light module has a first LED module and asecond LED module for emitting the first light and the second lightrespectively. The first LED module and the second LED module may bedisposed at different positions with different emitting directions. Insome embodiments, the first LED module and the second LED module emitlights may even have different optical spectrums, e.g. with differentcolor temperatures or colors.

In some embodiments, the light module may include a substrate, e.g. withaluminum material. The first LED module is disposed at a central portionof the substrate and the second LED module, which may include multiplesub-components, is disposed at a peripheral portion of the substrate.Specifically, the first LED module emits light to the light guide in thecentral position while the second LED module emits light to thediffusion cover to produce the peripheral light surrounding the light ofthe light guide.

In some other embodiments, the first LED module and the second LEDmodule are mounted on two different substrates. The two differentsubstrates are disposed at different heights with respect to the basepart. Unlike the example mentioned above in which both the first LEDmodule and the second LED module are dispose on the same substrate, thefirst LED module may be disposed on a substrate attached to the basepart of the main housing, while the second LED module is disposed at abetter position for rendering the peripheral light of the diffusioncover as requested.

For example, the second LED module may be positioned around the bottomend of the surrounding wall, with some wires for transmittingelectricity to the second LED module along the surrounding wall. Thesecond LED module now emits light more closely to the diffusion coverand may produce a better luminance efficacy.

The diffusion cover helps smooth output light, e.g. with roughenedsurface or coated with a translucent material for evenly guiding lightto form a smooth effect. The diffusion cover may be a light guide platewhen the light output points are carefully designed to create a lightevenly distributed appearance.

In some embodiments, the diffusion cover may include a peripheral lightguide. The second LED module emits the second light into the peripherallight guide to form the peripheral light. The peripheral light guide andthe light guide mentioned above may be made of various material likePMMA while adding light output paths thereon to guide light to passthrough the light guide and escape at multiple predetermined positionsto create desired light effect.

In some embodiments, both sides of the peripheral light guide emit theperipheral light. In some other embodiments, the back side of theperipheral light guide is covered with a reflective cover so as theperipheral light only emits from one side of the peripheral light guide.

In some embodiments, the light guide is an elongated column, e.g. acylinder, a polygonal column. The light escape side may further includea three-dimension shape for producing a corresponding three-dimensionluminance effect. For example, a crown, torch, letter, wire shapes maybe prepared on the light escape side of the light guide to produce acorresponding three-dimension shape of the light.

In some embodiments, the inner wall of the diffusion cover has athree-dimension surrounding inwardly curve surface. The inner wallrefers to the surface facing toward the light guide in the middle of thedownlight apparatus. The three-dimension surrounding inwardly curvesurface is gradually extended downwardly from near the base part of themain housing to form a smooth shape. Some drawings in followingdisclosure explains more clearly such concept.

In some embodiments, the diffusion cover protrudes below the bottom endof the surrounding wall. Specifically, when the downlight apparatus isplaced facing its light downwardly, the diffusion cover has a portionlower than the bottom end of the surrounding wall, thus forming aluminance ring.

In some embodiments, the three-dimension surrounding inwardly curvesurface is corresponding to the surrounding wall so as luminance levelover the diffusion cover is evenly distributed. Specifically, thesurrounding wall may have a similar but different curve surface so as toreflect or to re-direct light to emit on the diffusion cover so as asluminance level over the diffusion cover is evenly distributed.Therefore, when the surrounding wall changes its curve shape, thediffusion cover is adjusted accordingly. This may be determined by usingan optical analysis tool running on a computer, and then adjust thecurve surface of the diffusion cover to achieve the evenly distributedeffect.

In some embodiments, an interior side of the surrounding wall hasreflective material for reflecting light evenly over the diffusioncover. For example, an additional reflective component or reflectivematerial may be applied on the interior side of the surrounding wall.Alternatively, if the interior surface of the surrounding wall is madeof plastic like white PC board, the reflective effect may sufficient fitthe needs.

In some embodiments, luminance difference between any two positions ofthe diffusion cover is less than 30%. This means that the evenlydistributed level may be controlled and adjusted by adjusting the curvesurface and/or the reflective paths so that any two positions of thediffusion cover has similar luminance level, e.g. within 30% differencemaximum.

In some embodiments, instead of having only one light guide, there maybe multiple light guides in the middle of the downlight apparatus. Thelight escape sides of the these light guides may direct to differentdirections to form a different visual effect, e.g. like a flower or atorch. These light guides may even have different colors, depending ondifferent design needs.

In some embodiments, the base part has a back structure with two socketsfor selectively installing different fixing structures for fixing thedownlight apparatus to different stations. For example, in U.S.downlight standard, there are two elongated strips with their centerdisposed with a spring to adjusting an angle of the two elongatedstrips. In European downlight standards, there may be two elastic clipsfor hooking on a standard station.

The two sockets of the back structure may be fixed with different fixingstructures like the elastic clips of European standard or elongatedstrips of U.S. standard, depending on where the products are sold to. Inother words, such design ensures flexibility of the products, savinglots of manufacturing and storage cost.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is an exploded view showing components of a downlight apparatusembodiment.

FIG. 2 is a sectional view showing component relation when thecomponents of FIG. 1 are assembled.

FIG. 3 shows a bottom looking upwardly to the embodiment of FIG. 1.

FIG. 4 shows a first fixing structure for a U.S. downlight station.

FIG. 5 shows a second fixing structure for a European downlight station.

FIG. 6 shows component relation in another embodiment.

FIG. 7 shows another embodiment of a downlight apparatus.

DETAILED DESCRIPTION

Please refer to FIG. 1, FIG. 2 and FIG. 3 together. FIG. 1 is anexploded view showing components of a downlight apparatus embodiment.FIG. 2 is a sectional view showing component relation when thecomponents of FIG. 1 are assembled. FIG. 3 shows a bottom lookingupwardly to the embodiment of FIG. 1.

In FIG. 1, FIG. 2 and FIG. 3, the downlight apparatus has a main housingthat has a back structure 101, a base part 103 and a surrounding wall104. The back structure 101 has two sockets for installing differentfixing structures 1021 corresponding to different stations.

The surrounding wall has a top end 1041 fixed to the base part 103 and abottom end 1042 fixed to a diffusion cover 12.

In this example, a light module 11 includes a substrate mounted with afirst LED module 111 and a second LED module 112. The first LED module111 is disposed at center portion of the substrate while the second LEDmodule is disposed at peripheral portion of the substrate.

There is a light guide 13 disposed at center of the downlight apparatus,surrounding by the diffusion cover 12 and the surrounding wall 104. Thefirst LED module 111 emits a first light into the light guide 13 from alight entrance side 131. The light passes through the light guide 13 andemits from the light escape side 132 of the light guide. Athree-dimension shape is formed at the light escape side 132, e.g. acrown shape, for rendering a three-dimension visual effect.

The diffusion cover 12 is fixed to the bottom end 1042 of thesurrounding wall 104. The diffusion cover 112 converts a second lightfrom the second LED module 112 to a peripheral light emitting from theexterior surface 124 of the diffusion cover. The light effect of thediffusion cover 12 is smooth, to form a charming effect together withthe light guide 13.

The lateral side of the diffusion cover 12 has a three-dimensionsurrounding inwardly curve surface 122, corresponding to thethree-dimension curve surface of the surrounding wall 104. The interiorside of the surrounding wall helps reflect and guide the second light tosmoothly emit on the diffusion cover 12.

Please refer to FIG. 4, which illustrates the socket 42 may be attachedto an elongated strip 41 for U.S. downlight standard.

Please refer to FIG. 5, which illustrates the same socket 52 may beattached to an elastic clip for European standard.

According to an embodiment of the present invention, a downlightapparatus includes a main housing, a light module, a diffusion cover,and a light guide.

The downlight apparatus may be attached to a standard U.S. or Europeanstandard downlight station. The main housing may be made of plastic as apiece, e.g. made via a molding procedure to produce a one-piececomponent. Alternatively, the main housing may contain multiple parts tobe assembled together or adding further components like driver circuitor heat sink.

The main housing has a surrounding wall and a base part. A top end ofthe surrounding wall fixed to the base part forming a cup containingspace. For example, a surrounding wall is extended from the base partwith a surrounding curved surface. The surrounding curved surface andthe base part together form a cup containing space for enclosing somecomponents mentioned below.

The light module may have one LED module or multiple LED modules. Wherethere are multiple LED modules, the multiple LED modules at differentpositions on a substrate or on different substrates. Some specificexamples are explained as follows.

The light module is at least partly attached to the base part, meaningthat at least some component of the LED module is directly or indirectlyattached to the base part of the main housing. Specifically, as anexample, when the main housing is made of plastic material, a metal heatsink may be disposed between the base part of the main housing and a LEDplate of the light module.

In addition, the light module emits a first light and a second light. Asmentioned above, the light module may have multiple LED modules foremitting the first light and the second light.

The diffusion cover is fixed to a bottom end of the surrounding wall forconverting the second light to a peripheral light on an exterior surfaceof the diffusion cover. Furthermore, the light guide has a lightentrance side facing to the base part for directing the first lightthrough the light guide to escape at a light escape side of the lightguide. In other words, there are two light output from the diffusioncover and the light guide respectively.

The light escape side of the light guide is surrounded by diffusioncover. The term “surround” does not need to limit the light escape sidebeing at the same plane as the diffusion cover. Instead, the term“surround” refers that in a two-dimension protection aspect, the lightescape side is surrounded by the diffusion cover. In other words, thelight escape side may be higher than the diffusion cover while stillbeing surrounded by the diffusion cover when being viewed from atwo-dimension bottom view. The term “surround” is explained similarlyfor other components in this disclosure.

In some embodiments, the downlight apparatus further includes a driver.The driver controls the light module to emit the first light and thesecond light separately. In other words, the driver may be connected toa wire or wireless switch for users to manually control or for programcodes to automatically control so as to turn on or turn off the firstlight and the second light separately. Specifically, the first light maybe turned on while the second light is turned off, the first light maybe turned off while the second light is turned on, or the first lightand the second light are turned on at the same time. The luminancestrength of the first light and the second light, when needed, may betuned separately or with a predetermined relation, depending ondifferent design needs.

In some embodiments, the light module has a first LED module and asecond LED module for emitting the first light and the second lightrespectively. The first LED module and the second LED module may bedisposed at different positions with different emitting directions. Insome embodiments, the first LED module and the second LED module emitlights may even have different optical spectrums, e.g. with differentcolor temperatures or colors.

In some embodiments, the light module may include a substrate, e.g. withaluminum material. The first LED module is disposed at a central portionof the substrate and the second LED module, which may include multiplesub-components, is disposed at a peripheral portion of the substrate.Specifically, the first LED module emits light to the light guide in thecentral position while the second LED module emits light to thediffusion cover to produce the peripheral light surrounding the light ofthe light guide.

In some other embodiments, the first LED module and the second LEDmodule are mounted on two different substrates. The two differentsubstrates are disposed at different heights with respect to the basepart. Unlike the example mentioned above in which both the first LEDmodule and the second LED module are dispose on the same substrate, thefirst LED module may be disposed on a substrate attached to the basepart of the main housing, while the second LED module is disposed at abetter position for rendering the peripheral light of the diffusioncover as requested.

For example, the second LED module may be positioned around the bottomend of the surrounding wall, with some wires for transmittingelectricity to the second LED module along the surrounding wall. Thesecond LED module now emits light more closely to the diffusion coverand may produce a better luminance efficacy.

The diffusion cover helps smooth output light, e.g. with roughenedsurface or coated with a translucent material for evenly guiding lightto form a smooth effect. The diffusion cover may be a light guide platewhen the light output points are carefully designed to create a lightevenly distributed appearance.

In some embodiments, the diffusion cover may include a peripheral lightguide. The second LED module emits the second light into the peripherallight guide to form the peripheral light. The peripheral light guide andthe light guide mentioned above may be made of various material likePMMA while adding light output paths thereon to guide light to passthrough the light guide and escape at multiple predetermined positionsto create desired light effect.

In some embodiments, both sides of the peripheral light guide emit theperipheral light. In some other embodiments, the back side of theperipheral light guide is covered with a reflective cover so as theperipheral light only emits from one side of the peripheral light guide.

In some embodiments, the light guide is an elongated column, e.g. acylinder, a polygonal column. The light escape side may further includea three-dimension shape for producing a corresponding three-dimensionluminance effect. For example, a crown, torch, letter, wire shapes maybe prepared on the light escape side of the light guide to produce acorresponding three-dimension shape of the light.

In some embodiments, the inner wall of the diffusion cover has athree-dimension surrounding inwardly curve surface. The inner wallrefers to the surface facing toward the light guide in the middle of thedownlight apparatus. The three-dimension surrounding inwardly curvesurface is gradually extended downwardly from near the base part of themain housing to form a smooth shape. Some drawings in followingdisclosure explains more clearly such concept.

In some embodiments, the diffusion cover protrudes below the bottom endof the surrounding wall. Specifically, when the downlight apparatus isplaced facing its light downwardly, the diffusion cover has a portionlower than the bottom end of the surrounding wall, thus forming aluminance ring.

In some embodiments, the three-dimension surrounding inwardly curvesurface is corresponding to the surrounding wall so as luminance levelover the diffusion cover is evenly distributed. Specifically, thesurrounding wall may have a similar but different curve surface so as toreflect or to re-direct light to emit on the diffusion cover so as asluminance level over the diffusion cover is evenly distributed.Therefore, when the surrounding wall changes its curve shape, thediffusion cover is adjusted accordingly. This may be determined by usingan optical analysis tool running on a computer, and then adjust thecurve surface of the diffusion cover to achieve the evenly distributedeffect.

In some embodiments, an interior side of the surrounding wall hasreflective material for reflecting light evenly over the diffusioncover. For example, an additional reflective component or reflectivematerial may be applied on the interior side of the surrounding wall.Alternatively, if the interior surface of the surrounding wall is madeof plastic like white PC board, the reflective effect may sufficient fitthe needs.

In some embodiments, luminance difference between any two positions ofthe diffusion cover is less than 30%. This means that the evenlydistributed level may be controlled and adjusted by adjusting the curvesurface and/or the reflective paths so that any two positions of thediffusion cover has similar luminance level, e.g. within 30% differencemaximum.

In some embodiments, instead of having only one light guide, there maybe multiple light guides in the middle of the downlight apparatus. Thelight escape sides of these light guides may direct to differentdirections to form a different visual effect, e.g. like a flower or atorch. These light guides may even have different colors, depending ondifferent design needs.

In some embodiments, the base part has a back structure with two socketsfor selectively installing different fixing structures for fixing thedownlight apparatus to different stations. For example, in U.S.downlight standard, there are two elongated strips with their centerdisposed with a spring to adjusting an angle of the two elongatedstrips. In European downlight standards, there may be two elastic clipsfor hooking on a standard station.

The two sockets of the back structure may be fixed with different fixingstructures like the elastic clips of European standard or elongatedstrips of U.S. standard, depending on where the products are sold to. Inother words, such design ensures flexibility of the products, savinglots of manufacturing and storage cost.

Please refer to FIG. 6. FIG. 6 is used for explaining several conceptsof the features mentioned above.

Similar to the examples mentioned above, the downlight apparatus has abase part 601, a surrounding wall 603, a first LED module 6020, a secondLED module 6021, a diffusion cover 604.

The diffusion cover 604 is fixed to the bottom end 6033 of thesurrounding wall 603. The base part 601 is fixed to a top end 6032 ofthe surrounding wall 603. There is a protruding portion of the diffusioncover 604 below the bottom end 6033 of the surrounding wall 603. Thelight guide 611 has a light entrance side 6112 and a light escape side6111.

Some features are further explained as follows.

First, there may be multiple light guides 611, 612, and 613, which maybe curved and emits light to different directions.

Second, the three-dimension surrounding inwardly curve surface 6041 ofthe diffusion cover 604 may be adjusted according to a curved surface6031 of a different surrounding wall 603 so that the light may be evenlydistributed and appear on interior surface of the diffusion cover 604.

Please refer to FIG. 7, which illustrates another embodiment.

In FIG. 7, the first LED module 701 emits a first light to the lightguide 71. There is a second LED module 702 disposed at differentsubstrates as the first LED module 701 for emitting light into aperipheral light guide 703, which is like a disk with hole in centralposition. The front side 7032 and the back side 7031 of the peripherallight guide may emit the peripheral light. Alternatively, the back sideof the peripheral light guide may be attached with a reflectivecomponent to reflect light so as the peripheral light is emitted onlyfrom the front side 7032 of the peripheral light guide.

In addition to the above-described embodiments, various modificationsmay be made, and as long as it is within the spirit of the sameinvention, the various designs that can be made by those skilled in theart are belong to the scope of the present invention.

1. A lighting apparatus, comprising: a main housing having a surroundingwall and a base part, a top end of the surrounding wall fixed to thebase part forming a cup containing space; a light module at least partlyattached to the base part for emitting a first light and a second light;a light guide having a light entrance side facing to the base part fordirecting the first light through the light guide to escape at a lightescape side of the light guide, wherein the light escape side of thelight guide is surrounded by a peripheral light generated by diffusingthe second light.
 2. The lighting apparatus of claim 1, furthercomprising a driver, wherein the driver controls the light module toemit the first light and the second light separately.
 3. The lightingapparatus of claim 2, wherein the light module has a first LED moduleand a second LED module for emitting the first light and the secondlight respectively.
 4. The lighting apparatus of claim 3, wherein thefirst LED module and the second LED module emit lights with differentoptical spectrums.
 5. The lighting apparatus of claim 3, wherein thelight module further comprises a substrate, the first LED module isdisposed at a central portion of the substrate and the second LED moduleis disposed at a peripheral portion of the substrate.
 6. The lightingapparatus of claim 1, wherein the first LED module and the second LEDmodule are mounted on two different substrates, the two differentsubstrates are disposed at different heights with respect to the basepart.
 7. The lighting apparatus of claim 6, wherein a diffusion cover isused for converting the second light to the peripheral light, and thediffusion cover comprises a peripheral light guide, and the second LEDmodule emits the second light into the peripheral light guide to formthe peripheral light.
 8. The lighting apparatus of claim 7, wherein bothsides of the peripheral light guide emit the peripheral light.
 9. Thelighting apparatus of claim 1, wherein the light guide is an elongatedcolumn.
 10. The lighting apparatus of claim 9, wherein the light escapeside has a three-dimension shape for producing a correspondingthree-dimension luminance effect.
 11. The lighting apparatus of claim 9,wherein a diffusion cover is used for converting the second light to theperipheral light, and the diffusion cover defines an inner wallsurrounding the elongated column.
 12. The lighting apparatus of claim11, wherein an inner wall of the diffusion cover has a three-dimensionsurrounding inwardly curve surface.
 13. The lighting apparatus of claim11, wherein the diffusion cover protrudes below the bottom end of thesurrounding wall.
 14. The lighting apparatus of claim 12, wherein thethree-dimension surrounding inwardly curve surface is corresponding tothe surrounding wall so as luminance level over the diffusion cover isevenly distributed.
 15. The lighting apparatus of claim 14, wherein aninterior side of the surrounding wall has reflective material forreflecting light evenly over the diffusion cover.
 16. The lightingapparatus of claim 15, wherein luminance difference between any twopositions of the diffusion cover is less than 30%.
 17. The lightingapparatus of claim 1, wherein there are a plurality of the light guides.18. The lighting apparatus of claim 1, wherein the plurality of lightguides have light escape sides facing to different directions.
 19. Thelighting apparatus of claim 1, wherein the first light and the secondlight have different color spectrums.
 20. The lighting apparatus ofclaim 1, wherein the base part has a back structure with two sockets forselectively installing different fixing structures for fixing thedownlight apparatus to different stations.